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I wrote a recursion function in python to evaluate the sequence of an interpolation method.

It's graphically explained in this image:

enter image description here

f[x]=f(x) and f[x0,x1]= f[x1]-f[x0]) / (x1 - x0) and so when f[x0,x1,...xn]=f[all_leastFirst,allbutLast] / xlast-xfirst.

This is it then, recursively.

I had got the following code:

xxs=[]
yys=[]
coeficientes = []
h = {}
r = 0.0

def a_j(xx,yy):
    global r
    if len(yy) == 1:
        h[xx[0]] = yy[0]
        return yy[0]
    else:
        r = (a_j(xx[1:],yy[1:])  - a_j(xx[:-1],yy[:-1])) / (xx-1]-xx[0])
        h[''.join(str(i) for i in xx[::-1])]=r
        coeficientes.append(r)
        return ( r )

But it was needed to get as output an array with only the numbers marked in a green circle. I was lost about how to get only those in a recursive implementation. One common pattern about them will be they ALWAYS start at X_0, so I opted about tagging them or using a dictionary might help.

Expected result would be:

[1,1.71828,1.47625,.84553]

I was obtaining:

[1, 2.71828, 7.3890599999999997, 20.085540000000002, 1.71828, 4.6707799999999997, 12.696480000000001, 1.4762499999999998, 4.0128500000000003, 0.84553333333333347]

For another run wit different parameters, if it's called by:

a_j([1,2,3,5][4,3.5,4,5.6])

Should output:

[4,-0.5,0.5,-0.1]

I was obtaining:

[4, 3.5, 4, 5.6, -0.5, 0.5, 0.5, 0.7999999999999998, 0.09999999999999994, -0.10000000000000002]

Another example:

a_j([-2,-1,0,1,2], [13,24,39,65,106])

Will output:

[13, 24, 39, 65, 106, 11, 15, 2, 26, 5, 1, 41, 7, 0, -1]

But the output should be:

[13,11,2,1.167,-0.125]

I also managed to code this iterative implementation, which is already correct:

diferencias = {}
coeficientes = []

def sublists_n(l, n):
    subs = []
    for i in range(len(l)-n+1):
        subs.extend([l[i:i+n]])
    return subs

def sublists(l):
    subs = []
    for i in range(len(l)-1,0,-1):
        subs.extend(sublists_n(l,i))
    subs.insert(0,l)
    return subs[::-1]


def diferenciasDivididas(xx,yy,x):

    combinaciones = sublists([i for i in range(len(xx))])

    for c in combinaciones:

        if len(c) == 1:
            diferencias[str(c[0])]= float(yy[c[0]])
            if c[0] == 0:
                coeficientes.append(float(yy[c[0]]))

        else:
            c1 = diferencias.get(''.join(str(i) for i in c[1:]))
            c2 = diferencias.get(''.join(str(i) for i in c[:-1]))

            d = float(( c1 - c2 ) / ( xx[c[len(c)-1]] - xx[c[0]] ))

            diferencias[''.join(str(i) for i in c)] = d

            if c[0] == 0:
                coeficientes.append(float(d))

I only wonder what was I missing?

share|improve this question
    
What is the expected result? –  thefourtheye Mar 12 '14 at 3:34
    
Can you please explain how is f[x0, x1] = 1.71828? As per your formula, it should have been much lesser value. –  thefourtheye Mar 12 '14 at 3:44
    
@thefourtheye As that's f(x1)-f(x0)/(x1-x0) that's 2.71828-1/(1-0) –  diegoaguilar Mar 12 '14 at 3:47
    
I managed to get the second column right and I don't understand the third column now :( –  thefourtheye Mar 12 '14 at 4:06
    
I got [1.71828, 4.67078, 12.696480000000001], but the next column I got is [2.9524999999999997, 8.0257] –  thefourtheye Mar 12 '14 at 5:23

4 Answers 4

up vote 1 down vote accepted

I have modified the script a bit.

    array=[]
    r='s'
    s=0
    def a_j(xx,yy):
        global r,s
        if r == 's':
            s=xx[0]
            r=0.0
        if len(yy) == 1:
            if xx[0]==s: array.append(yy[0])
            return float(yy[0])

        else:
            r=( a_j(xx[1:],yy[1:])  - a_j(xx[:-1],yy[:-1])) / (xx[-1]-xx[0])
            if xx[0]==s: array.append(r)
            return float(r)

    a_j([1,2,3,5],[4,3.5,4,5.6])
    print array

Output: [4, -0.5, 0.5, -0.10000000000000002]

also, the second example that you have given doesnt look correct. a_j([-2,-1,0,1,2], [13,24,39,65,106]) --> [13,11,4,7,-3]

above answer says that the 3rd element is 4.

    3rd element means --> x(-2,-1,0) -> x(-1,0)  -  x(-2,-1)/(2)
                                     -> x(0)-x(-1)/1  -  x(-1)-x(-2)/(1) /(2)
                                     ->(39-24) - (24-13)   /(2)
                                     ->15-11/(2)
                                     ->4/2 =2

Please correct me if i am wrong.

share|improve this answer
    
Yes, 3rd example was just wrong, my apologies. I would only add to cast to float the return values to get right results. I actually don't know why they just can't work as it, because they happen to be integers first? You're eager SO needs, thanks! –  diegoaguilar Mar 13 '14 at 11:51
    
Also, why exactly should r and s global? –  diegoaguilar Mar 13 '14 at 11:53
    
Could you give an eye to my edit and give opinion on my iterative implementation. And finally, what was I missing in my recursive implementation? (I think that wrong example fooled my and confused me) –  diegoaguilar Mar 13 '14 at 12:02
    
Thanks for the edit. You are correct. r and s are global because we need to check the value of these variables in and only in the first iteration. Couldnt find any better solution. Your code was looking good. I think that example confused you. –  sanooj Mar 13 '14 at 12:08
1  
i made it global since we need the initial values inside the function only once. If it was a local variable, it will assign the value to the variables every time the function is called. Which will satisfy the first conditional statement always. We need to fetch the first element of the original elements passed to the function. It can be done only during the first iteration of the function. –  sanooj Mar 14 '14 at 3:56

You are getting negative values here because you have not enclosed the subtraction in parenthesis.Otherwise the code looks good.

   r = ( a_j(xx1,yy1)  - a_j(xx0,yy0)  ) / (xx[len(xx)-1]-xx[0])

http://www.mathcs.emory.edu/~valerie/courses/fall10/155/resources/op_precedence.html

share|improve this answer
    
That helps a bit, but it's not exactly my error. Thanks though –  diegoaguilar Mar 12 '14 at 6:23

Try this:

    array=[]
    h={}
    r=0

    def a_j(xx,yy):
        global r
        if len(yy) == 1:
            h[int(xx[0])]=yy[0]
            return yy[0]

        else:
            r=( a_j(xx[1:],yy[1:])  - a_j(xx[:-1],yy[:-1])) / (xx[-1]-xx[0])
            h[int(''.join(str(i) for i in xx[::-1]))]=r
            return r

    a_j([0,1,2,3], [1,2.71828,7.38906,20.08554])
    array=[h[key] for key in  sorted(h.keys())]
    print array

Output: [1, 2.71828, 7.3890599999999997, 20.085540000000002, 1.71828, 4.6707799999999997, 12.696480000000001, 1.4762499999999998, 4.0128500000000003, 0.84553333333333347]

In this code, the values are first assigned to a dict with keys as the elements of xx reversed and converted to an integer.

share|improve this answer
    
Thanks so much, your answer really helped me. I just realized I actually need to get only some of the values calculated, I edited my question, my apologies. –  diegoaguilar Mar 12 '14 at 15:30

Since you are doing recursion, you will append each value as it exits the function, you will wind up getting the appending done in reverse xn, ... , x3, x2, x1

Once you finish the total recursion and exit for the last time, just reverse the list, which is relatively simple by several methods and has been asked before. I leave the method you want to use up to you (or remember "Google is your friend")

share|improve this answer

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